Synthesis and Reactivity of Low-Valent Amido, Imido, Azavinylidene

Organometallics 1994, 13, 1851-1864

1851

Synthesis and Reactivity of Low-Valent Amido, Imido, Azavinylidene, and Nitrido Complexes of Tungsten K. R. Powell, P. J. PBrez, L. Luan, S. G. Feng, P. S. White, M. Brookhart,* and J. L. Templeton* Department of Chemistry, University of North Carolina, Chapel Hill, North Carolina 27599-3290 Received December 27, 1993@ Amido complexes Tp’(C0)zW(NHR) [Tp’ = hydridotris(3,5-dimethylpyrazolyl)borate;R = But, la; R = Ph, lb; R = Bun, IC; R = CHZPh, Id; R = H, le] have been synthesized by reaction of the corresponding amine (NHzR) with Tp’(C0)2WI (2). These ambiphilic amido complexes have been utilized as precursors to both anionic imido complexes, Tp’(CO)zW(NR)- (R = Ph, 3a; R = CHZPh, 3b; R = H, 3c), and cationic imido complexes, Tp’(CO)zW(NR)+ (R = But, 5a; R = Ph, 5b; R = Bun, 5c; R = CHZPh, 5d; R = H , 6a; R = CPh3,6b). Treatment of the unstable anionic imido species 3a-c with PhCHzBr (3a) or Me1 (3b,c) leads to the formation of dialkyl substituted amido complexes Tp’(CO)zW(N(R)R’) (R = Ph, R’ = CHZPh, 4a; R = CHZPh, R’ = Me, 4b; R = R’ = Me, 4c). The structures of 4a and 4c have been confirmed by X-ray diffraction. (4aCHzClzcrystallizes in space group Pi with 2 = 2, a = 11.452(2) A, b = 11.597(2) A, c = 14.144(2) A, (Y = 86.78(1)”, p = 84.41(1)”, y = 64.37(1)”, R = 3.7%, R, = 4.6%; 4c crystallizes in space group Pi with 2 = 2, a = 11.151(4) A, b = 11.702(3) A, c = 10.391(4) A, (Y = 93.46(3)”, p = 108.56(3)”, y = 63.20(3)”, R = 3.976, R, = 4.3%.) Reactivity studies were carried out with the cationic nitrene complexes, Tp’(C0)2W(NR)+. Deprotonation of Tp’(CO)zW(NCH2R)+ (R = Prn, 5c; R = Ph, 5d) yields azavinylidene complexes, Tp’(C0)zW(N=CHR) (R = Prn, 7a; R = Ph, 7b). The barrier to rotation around the WNC unit of 7a as determined by variable temperature NMR studies is 9.6 kcal/mol. Addition of LiBH4 to the cationic nitrene complex 5b results in formation of a formyl intermediate, Tp’(CO)(CHO)W(NPh) (S),which undergoes hydride migration from carbon to nitrogen t o form the amido complex lb a t -70 “C. Deprotonation of the parent nitrene cation Tp’(C0)2W(NH)+ (6a) or reaction of [(PhsP)zNI [N31 with Tp’(C0)2WI (2) yields an unstable nitrido complex Tp’(C0)zWN (9). Complex 9 reacts with a variety of electrophiles (RX) to form both dicarbonyl, [Tp’(CO)zW(NR)][X] (R = H, X = BF4-, 6a; R = CPhB, X = PFG-,6b; R = Me, X = OTf-, lo), as well as monocarbonyl, Tp’(CO)(X)W(NR) (R = Ts, X = C1, l l a ; R = C(O)CH3, X = C1, llb; R = C(0)CH3,X = OC(O)CH3,1IC), imido products. The X-ray structures of nitrene complexes Tp’(C0)2W(NPh)+(5b) and Tp’(CO)ClW(NTs) (1 la) reveallinear imido ligands for both cationic and neutral complexes with WN bond lengths of 1.775(7) and 1.78(1) A, respectively. (5b crystallizes in space group P21/n with 2 = 4, a = 10.301(2) A, b = 10.389(2) A, c = 27.816(7) A, p = 97.69(2)”, R = 3.6%, R, = 4.5%; l l a crystallizes in space group P21 with 2 = 2, a = 8.222(3) A, b = 17.256(6) A, c = 9.561(4) A, p = 100.85(3)’, R = 4.0%, R, = 4.6%.)

Introduction Despite the plethora of structurally characterized transition metal nitrene (or imido) complexes,1p2 the reactivity of the ligand itself has received relatively little attention. Although nitrene intermediates have been proposed in the Haber ammonia ~ynthesis,~ nitrile reduction: and ammoxidation of propylene,5 the majority of isolated nitrene complexes contain linear, unreactive imido ligands, a property compatible with their role as ligands for the stabilization of high metal oxidation states.2 Complexes with bent imido ligands have been structurally

* Abstract published in Advance ACS Abstracts, April 1, 1994.

(1) Accordingto IUPAC rules, the term “imido” is preferred to “nitrene” to describe M(NR) complexes. “Nitrene” is a familiar term which has found widespread acceptance and has been used more frequently, but not exclusively, to describe species which contain an electron deficient nitrogen. Herein, we use both the terms ‘imido” and’nitrene” to describe M(NR) complexes. (2) For reviews of imido complexes, see: (a) Nugent, W. A.; Haymore, B. L. Coord. Chem. Reu. 1980,31,123. (b) Nugent, W. A.; Mayer, J. M. Metal-Ligand Multiple Bonds; Wiley-Interscience: New York, 1988. (c) Cenini, S.; La Monica, G. Znorg. Chim. Acta 1976, 18, 279. (3) Fjare, D. E.;Gladfelter, W. L. J. Am. Chem. SOC.1981, 103, 1572. (4) Andrews, M. A.; Kaesz, H. D. J. Am. Chem. SOC.1979,101,7255. ( 5 ) Burrington, J. D.; Grasselli, R. K. J. Catal. 1979, 59, 79.

0276-7333/94/2313-l851$04.50/0

characterized as well. In general, bending of an imido ligand occurs when lone pair donation would result in a complex with an electron count exceeding eighteen.6 These linear and bent bonding modes suggest structural analogies with oxo, carbene, and carbyne ligands.2b If this analogy between nitrene and oxo or carbene systems is extended to reactivity, imido complexes have potential as nitrene transfer agents in organic synthesis. One of the first examples of this utility was the amination of olefins with osmium imido reagents developed by Sharpless and coworkers.7 In terms of reactivity, the nitrene ligand may be nucleophilic or electrophilic at nitrogen. Many nucleophilic imido species react with aldehydes or ketones to give organic imines.8 For example, the putative zerovalent complex (C0)5W(NPh) reacts with a variety of electrophilic aldehydes, ketones, and thioketones to produce free (6)Etzdtc = NN-diethyldithiocabamate. (a) Maatta, E.A,;Haymore, B. L.; Wentworth, R. A. D. Znorg. Chem. 1980,19,1055. (b) Maatta, E. A.; Haymore, B. L.; Wentworth, R. A. D. Znorg. Chem. 1979, 18, 2409. (7) (a) Sharpless, K. B.; Teranishi, A. Y.; Backvall, J.-E. J.Am. Chem. Oshima, K.; Sharpless, K. B. J.Am. SOC.1977,99,3120. (b) Chong, A. 0.; Chem. SOC.1977, 99, 3420. (c) Patrick, D. W.; Truesdale, L. K.; Biller, S. A.; Sharpless, K. B. J. Org. Chem. 1978, 43, 2628.

0 1994 American Chemical Society

Powell et al.

1852 Organometallics, Vol. 13, No. 5, 1994

organic imine^.^ Bending of the imido ligand is generally believed to increase its nucleophilicity. The classic example of this behavior is the protonation (or methylation) of a single imido ligand of (Etzdtc)zMo(NPh)zwhich contains one linear and one bent imido unit.6 More recently, a reactive low valent linear nitrene complex, Cp*IrNBut, has been reported which reacts with MeI, CO, and CNBut and also undergoes 2 + 2 reactions with COP and an alkyne.10 Bergman and Wolczanski have proposed that transient nucleophilic zirconium imido species, [Cp2Zr=NBut] and [(But3SiNH)2Zr=NSiBut31, respectively, promote intermolecular C-H bond activation.” Likewise, deuteration of the amido protons of (But3SiNH)2(EtzO)Ti=NSiBu$ in the presence of C6D6 is proposed to occur via the transient imido species [(But3SiNH)2Ti=NSiBut31 .I2 Nitrene complexeswith reactivity patterns that indicate electrophilic character at nitrogen are rare. Electrophilic nitrenes tend to be difficult to observe or isolate, and details of their reactivity are not well understood. The aforementioned amination of olefins by osmium imido complexes has been proposed to proceed by initial association of the olefin with an electron deficient nitrene ligand.’ Another early example of apparent electrophilicity at nitrogen is the reaction of (Me3SiO)2Cr(NBut)2with Ph2Zn which yields tert-butylaniline upon hydr01ysis.l~ Sulfuric or hydrochloric acid decomposition of [Ir(NH3)5N3I2+to give [Ir(NH3)5NH20S03I2+or [Ir(NH3)5NHzC1]3+, respectively, is proposed to proceed through an electrophilic nitrene intermediate [Ir(NH3)5NH13+ which reacts with HSO4- or C1-, re~pective1y.l~ A number of electrophilic nitrene complexes add phosphine at nitrogen to form phosphine imides. Ambiphilic (CO)5W(NPh), noted earlier for its nucleophilic reactivity, is trapped with PPh3 to form the coordinated phosphine imide.’5 The related heteroatom stabilized nitrene (C0)5W(NNMe2)undergoes CO substitution with PPh3 and DPPE in preference to phosphine addition at nitrogen although reaction with DPPM yields the metalla-

phyrin imido complexes react with PPh3 to yield the free phosphine imides, Ph3P=NR,1* Similarly,the homoleptic imido complex Os(N-2,6-CsH3Pri2)3reacts with PMe2Ph to yield PhMezP=NAr and 0s(NAr)2(PMe2Ph)2.l9 Additionally, Mo(NTs)z(Etzdtc)z carries out similar nitrene transfer to phosphine catalytically using PhMeSNTs or PhsSbNTs as the nitrene source.2o Recent reports of enantioselective nitrene transfer in catalytic aziridination reactions2’ are particularly significant because of promising applications to asymmetric synthesis.22 Jacobsen and eo-workers have developed chiral diimine-copper(1) complexes which effect enantioselective aziridination of a variety of olefins utilizing PhI=NTs as the nitrene source.21a Concurrently, Evans has reported good yields of aziridines generated by enantioselective nitrene transfer from PhI=NTs to olefins catalyzed by chiral bis(oxazo1ine)copper complexes.21b Previously, a number of copper systems that catalyze nitrene transfer from PhI=NTs to olefins were known21Gd*a although only two enantioselective reactions had ever been described (both with c h i d bis(oxazo1ine)ligands).21c*dThe intermediacy of electrophilic metal nitrenes has been proposed in these copper s y ~ t e m s ~as l pwell ~ ~ as in earlier reports of manganese and iron porphyrin catalyzed nitrene transfer systems.24In catalytic cyclopropanationreactions a catalytic carbene species has only recently been observed;25the putative nitrene intermediate is elusive as well. This paper reports general routes to cationic, anionic, and neutral tungsten nitrene complexes; portions have been communicated earlier.26 Neutral amido complexes, Tp’(C0)2W(NHR) [R = But (la),Ph (lb),Bun (IC), CH2Ph (Id), and H (le)],serve as precursors to both cationic, Tp’(C0)2W(NR)+,and anionic, Tp’(C0)2W(NR)-, imido complexes. The nature of the nitrene nitrogen of the cationic complexes appears to be electrophilic while that of the anionic complexes is nucleophilic. The conversion of cationic nitrene complexesto amido, azavinylidene, and nitrido complexes is described in detail. The synthetic utility of the nitrido complex,Tp’(CO)zWN,as a precursor to new imido complexes is established.

(17)Fourquet, J. L.; Leblanc, M.; Saravanamuthu, A.; Bruce, M. R. cyclic phosphinimine, (C0)4W(PPh2CH2PPh2)NNMe2.16 M.; Bruce, A. E. Inorg. Chem. 1991,30, 3241. Likewise, the putative nitrene intermediate from the (18)(a) Huang, J.-S.; Che, C.-M.; Poon, C.-K. J . Chem. SOC., Chem. Commun. 1992,161.(b) EUiot,R. L.;Nichols,P. J.;West, B. 0.Polyhedron reaction of ~ u c - M o ( C O ) ~ ( N C C H ~with ) ~ P P8-azido~~ 1987,6, 2191. quinoline is trapped by phosphine to yield (CO)r(19)Anhaus, J. T.; Kee, T. P.; Schofield, M. H.; Schrock, R. R. J. Am.

Mo[N(PPhs)(C9H6N)1.l7Ruthenium and chromium por~

(8)(a) Cotton, F. A.; Hall, W. T. J. Am. Chem. SOC. 1979,101, 5094. (b) Rocklage, S. M.; Schrock, R. R. J. Am. Chem. SOC.1980,102,7808. (c) Rocklage, S. M.; Schrock, R. R. J. Am. Chem. SOC. 1982,104,3077. (d) Nugent, W. A. Inorg. Chem. 1983,22,965. (9)Arndtaen, B. A.; Sleiman, H. F.; Chang, A. K.; McElwee-White, L. J. Am. Chem. SOC. 1991,113,4871. (10)(a) Glueck, D. S.; Hollander, F. J.; Bergman, R. G. J . Am. Chem. SOC. 1989,111,2719.(b) Glueck,D. S.;Wu, J.;Hollander,F.J.;Bergman, 1991,113,2041. R. G. J . Am. Chem. SOC. (11)(a) Cummins, C. C.; Baxter, S. M.; Wolczanski, P. T. J.Am. Chem. SOC. 1988,110,8731. (b) Walsh, P. J.; Hollander, F. J.; Bergman, R. G. J. Am. Chem. SOC.1988,110,8729. (c) Walsh, P. J.; Baranger, A. M.; Bergman, R. G. J . Am. Chem. SOC.1992,114,1708. (12)Cummins, C. C.; Schaller, C. P.; Van Duyne, G. D.; Wolczanski, P. T. J. Am. Chem. SOC. 1991,113,2985. (13)Nugent, W. A.; Harlow, R. L. J.Am. Chem. SOC. 1980,102,1759. (14)(a)Lane,B.C.;McDonald, J.W.;Basolo,F.;Pearson,R. G. J . A m . Chem. SOC. 1972,94, 3786. (b) Gafney, H. D.; Reed, J. L.; Basolo, F. J . Am. Chem. SOC. 1973,95, 7998. (15)Sleiman, H. F.;Mercer, S.; McElwee-White, L. J.Am. Chem. SOC. 1989,111, 8007. (16)Arndtsen, B. A.; Sleiman, H. F.; McElwee-White, L.; Rheingold, A. L. Organometallics 1993,12, 2440.

1990,112,1642. Chem. SOC. (20)Etzdtc = N,N’-diethyldithiocarbamate.Harlan, E. W.; Holm, R. H. J . Am. Chem. SOC. 1990,112,186. (21)(a) Li, Z.; Conser, K. R.; Jacobsen, E. N. J . Am. Chem. SOC. 1993, 115,5326. (b) Evans, D. A,; Faul, M. M.; Bilodeau, M. T.; Anderson, B. A.; Barnes, D. M. J . Am. Chem. SOC. 1993,115,5328.(c) Evans, D. A.; Faul, M. M.; Bilodeau, M. T.J . Org. Chem. 1991,56,6744.(d) Lowenthal, R. E.; Masamune, S. Tetrahedron Lett. 1991,32, 7373. (22)(a) Swift, G.; Swern, D. J. Org. Chem. 1967,32,511. (b) Tseng, C. C.; Terashima, S.; Yamada, SA. Chem. Pharm. Bull. 1977,25,166.(c) Padwa, A.; Woolhouse, A. D. Aziridines, Azirines, and Fused-ring Derivatives. In Comprehensiue Heterocyclic Chemistry; Lwowski, W., Ed.; Pergamon Press: Oxford, U.K., 1984;Vol. 7. (23)(a) Evans, D. A.; Woerpel, K. A.; Hinman, M. M.; Faul, M. M. J. Am. Chem. SOC. 1991,113,726.(b) O’Connor, K.J.; Wey, S.-J.; Burrows, C. J. Tetrahedron Lett. 1992,33,1001. (c) PBrez, P. J.; Brookhart, M.; Templeton, J. L. Organometallics 1993,12, 261. (24)(a) Mansuy, D.; Mahy, J.-P.; Dureault, A.; Bedi, G.; Battioni, P. J . Chem. SOC.,Chem. Commun. 1984,1161.(b) Mansuy, D.; Mahy, J.-P.; Bedi, G.; Battioni, P. J . Chem. SOC.,Perkin Trans. 2 1988,1517. (c) 1983,105,2073. Groves, J. T.; Takahashi, T. J . Am. Chem. SOC. (25)Smith, D.A.; Reynolds, D. N.; Woo, L. K. J. Am. Chem. SOC. 1993, 115,2511.

(26)(a) Luan, L.; White, P. S.; Brookhart, M.; Templeton, J. L. J . Am. 1990,112,8190.(b) Luan, L.; Brookhart, M.; Templeton, J. Chem. SOC. L. Organometallics 1992,11, 1433. (c) PBrez, P. J.; Luan, L.; White, P. S.; Brookhart, M.; Templeton, J. L. J. Am. Chem. SOC.1992,114, 7928.

Tungsten Imido Complexes H

Organometallics, Vol. 13,No. 5, 1994 1853 1-

anti

SYn

Figure 2. Anti and syn isomers of Tp’(CO)zW(NHR). possible isomers (see Figure 21, one with R oriented away from the bulky Tp’ ligand (anti) and one with R located near the Tp’ ligand (syn). lH NMR signals in the range 10-16 ppm are diagnostic for coordinated amido protons (NHR). Tp’(C0)zW(NHBu”) (IC) and Tp’(C0)2W(NHCH2Ph) (Id) exist as a 6:l mixtures of two isomers in solution at room temperature, as indicated by their lH NMR signals for the amido hydrogens at 13.7 and 11.9 ppm (IC) and 13.6 and 11.8 ppm (Id),respectively (see Table 2 for lH NMR data). Tp’(C0)2W(NHPh) (lb) also exists as a mixture of two isomers in solution. In this case, the major isomer can be separated by crystallization and obtained as a solid. Kinetics experiments on formation of the second isomer of l b have been carried out at 22 OC. Upon dissolution of crystals of the major isomer of l b (15.3 ppm, NH) in CD2C12, the minor isomer (13.0 ppm, NH) is observed to grow in over 5 days. The minor isomer accounts for 11.8% of the total material at equilibrium which corresponds to Keq = 0.13. The interconversion of the two isomers (eq 4) is a first order process with rates of interconversion k l = 7.0 X lo4 s-1 and k-1 = 5.2 X s-l corresponding to AG*= 24.2 kcal/mol and AG* = 23.0 kcal/mol, respectively.

la lb IC

Id le

Bu‘ Ph Bun CH2Ph H

CHpCh,25 ‘C CHPC~, 25 “C THF,25”C CHzCh, 25 “C CH,C$, -50 “C

(27) Feng, S. G.; Templeton, J. L. Organometallics 1992,11, 2168.

For the Tp’(C0)2W(NHR) complexes we propose that restricted rotation around the tungsten amide multiple bond is the mode of isomerization. When R is very bulky (But, la), only the favored isomer is observed. Complex la displays a single NH resonance at 14.15 ppm. We propose a static anti geometry for this complex based on the steric hindrance of the bulky But group compared to the hydrogen atom. When R is somewhat less bulky (Ph, lb; Bun, IC; CHzPh, Id), two isomers, syn and anti, are observed in solution. Two broad signals at 13.5 and 11.6 ppm in the room temperature ‘H NMR spectrum of the parent amido complex Tp’(C0)2W(NH2) (le) are assigned to the two amido protons. These signals coalesce at 103 “C, corresponding to AG* = 17 kcal/mol. Thus this barrier to rotation is significantly lower than the barriers for interconversion of the syn and anti isomers of Tp’(C0)zW(NHPh) (lb) described above. Rotation around the tungsten-nitrogen bond in Tp’(C0)2W(NHPh) (lb) may be expected to be more restricted than that in Tp’(C0)zW(NH2) (le)based on the steric encumbrance of the phenyl group which must rotate past the Tp’ methyl groups. Deprotonation of Tp’(CO)zW(NHR) amido complexes lb, Id, and l e with LDA (lithium diisopropylamide) (Id and le) or ButLi (lb) yields reactive dicarbonyl species. On the basis of the low carbonyl stretching frequencies (1750 and 1652cm-l, lb; 1858and 1720 cm-’, Id; 1861and 1724 cm-1, le), we propose that anionic tungsten nitrene

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Powell et al.

Table 1. IR Data8 for la-e, 2, 4a-c, 5a-d, 6a,b, 7a,b, 9, 10, and lla-c complex

u(CO)b

la, Tp’(C0)2W(NHBut) Ib,Tp’(C0)2W(NHPh) IC,Tp’(C0)2W(NHBun) Id, Tp’(C0)2W(NHCH2Ph) le, Tp’(C0)2W(NHd 2,Tp’(C0)2WI 3a, [Li] [Tp’(C0)2W(NPh)] 3b, [Li] [Tpt(CO)2W(NCH2Ph)]

1910,1782 1900,1786 1911,1794 1910,1784 1915,1793 1944,1844 1750,1652 1858,1720 1861,1724 1914,1787 1904,1777 1904,1777 208 1,2003 2079,2006 2082,2004 2083,2006 2092,2017 2083,2008 1923,1815 1942,1830 2041, 1944 2083,2006 1969 1954 1948

l l a , Tp’(CO)ClW(NTs) 1lb, Tp’(CO)ClW(NC(O)CH3) 1IC,Tp’(CO)(OC(O)CH3)W(NC(O)CH3) a

other 3260,3 121 (N-H)C 3231,3138 (N-H)c 3260,3125 (N-H)c 3311,3261 (N-H)C 3395,3305 (N-H)C

v(BH)~

U(PF)~

2546 2548 2540 2544 2540

2540 2536

3328 (N-H)C 1628 (C=N)b 1559 (C=N)b

1674 (-C(0)-)b 1674, 1645 (-C(0)-)b

2589 2577 2565 2577 2582 2575 2582

849 84 1 843 844 841

258 1 2557 2559

844

In cm-I. CH2C12 solution. Nujol mull.

Figure 3. Schematic representation of amido orientation. C15

complexes, [Lil [Tp’(C0)2W(NR)I (3a-c), are formed (eq 5). These anionic dicarbonyl nitrene complexes are susTp’(CO)zW’+=

NHR

LDA or Bu’Li

l b , I d , le

..1ti+

Tp’(C0)zW =NR complex

THF

c

]R’X

Tp’(CO),WC-NRR’

complex

R

4a 4b

R

1 1 h;HP ,h

3c

(5)

R’X

Figure 4. ORTEP diagram of Tp’(CO)zW(N(Ph)CH2Ph) (4a).

PhCH2Br Me1

ceptible to protonation by traces of moisture to reform the starting material, Tp’(CO)zW(NHR). When quenched with alkylating agents at low temperature, however, dialkyl substituted amido complexes 4a-c are formed. In the reaction of Tp’(C0)2W(NH2) (le) with base followed by Me1 (eq 6),double alkylation occurs. Under these reaction

1. base

Tp’(C0)zWtNHz le

2. Me1 (excess)

Tp’(C0)2W=NMe2

(6)

4c

conditions, perhaps any Tp’(C0)2W(NHMe) formed is susceptible to deprotonation which is followed by methylation by excess MeI. Spectroscopic data for 4a-c are similar to those observed for la-e (vide supra; see Tables 1and 2). Consequently, we propose a similar structural formulation for 4a-c (Figure 3). Single crystal X-ray diffraction studies of Tp’(C0)2W(N(Ph)CH2Ph)(4a) and Tp’(C0)2W(NMe2) (4c) unequivocally establish the geometry of these complexes and confirm that the NRR’ moiety lies in the molecular

mirror plane. Figures 4 and 5 show ORTEP diagrams of Tp’(CO)zW(N(Ph)CHzPh) (4a) and Tp’(C0)2W(NMe2) (4c). The crystallographic data and collection parameters for 4a and 4c are given in Table 3; Tables 4-7 present atomic parameters and selected bond distances and angles for 4a and 4c. The 1.981(6)-A (4a) and 1.956(5)-A (4c) W-N distances are appropriate for tungsten-nitrogen double bonds, as found in Chisholm’s tungsten amido complexes.28 Although tungsten hydrazido species are sometimes considered to have metal-nitrogen double bonds, the two-coordinate nitrogen in W-N-NR2 systems exhibits W-N distances well below 2.0 A and more in the range typical of tungsten nitrenes.2b The amide nitrogens are roughly sp2 hybridized on the basis of bond angles: W (1)-N( 3)-C(4), 122.7(4)’; W(1)-N( 3)-C( 21), 125.6(4)O ; and C(4)-N(3)-C(5), 111.1(5)’ (4a) and W(l)-N(3)-C(4), 128.7(5)’; W(1)-N(3)-C(5), 121.2(4)O ;and C(4)-N(3)-C(5), 110.1(6)O(4c). The WNRR’ skeletons are planar and are located in the mirror plane of the molecules. The phenyl (28) Buhro, W.E.;Chisholm,M.H.;Folting,K.;Huffman, J.C.;Martin, J. D.; Streib, W. E. J. Am. Chem. SOC.1992, 114, 557.

Organometallics, Vol. 13, No. 5, 1994 1855

Tungsten Imido Complexes

bd,

Px

Figure 7. Drawings of the metal da-nitrogen pa interactions for Tp’(C0)2W(NR)+(5a-d, 6a,b, 10) and Tp’(CO)2WN (9). (lb), R = Bun (IC), and R = CH2Ph (Id)] with [Ph3C][PFc] at low temperature yields cationic dicarbonylimidotungsten(1V)d2complexes, [Tp’(C0)2W(NR)I[PF61 [(R = But (5a), R = Ph (5b), R = Bun (5c), and R = CH2Ph (5d),respectively] (eq 7). Similar treatment of Tp’(C0)2WTp‘(CO)2W=

NHR

[Ph3CI[PF61 CH2Cl, 0 “c

l a , l b , IC, Id

-- T p ‘ ( C O ) 2 W s N z +

(7)

Sa, 5b, 5c, 5d

R = But (a), Ph (b), Bun (c), CH2Ph (d) -

Figure 5. ORTEP diagram of Tp’(C0)2W(NMe2) (4c).

(NH2) (le) with [Ph3C] [PF6] yields not only the expected hydride abstraction product, [Tp’(C0)2W(NH)I[PFe] (6a), but also another cationic nitrene complex, [Tp’(C0)2W(NCPh3)1[PF6] (6b) (eq 8). Complexes 6a and 6b, present in a 4:l ratio, respectively, are separable by crystallization.

le

Figure 6. Drawing of the metal da-nitrogen pa interactions for Tp’(CO)2W (NRR’).

Tp‘(CO)*W=NH 6a

group of 4a is situated anti to the Tp’ ligand, as expected on the basis of the relative sizes of the phenyl and benzyl groups. As shown in Figure 6 and explained below, for acute OC-M-CO angles optimal a-bonding occurs when the amide (NRR’) is in the mirror plane.29 This vertical arrangement allows donation from the nitrogen (py) into the lone vacant d a orbital (dy,). The two filled d a orbitals (d,, and d , ~ ~ 2are ) stabilized by back-bonding to the two a-acid carbonyl ligands. Preferential stabilization of the filled d,, orbital occurs when the angle between the carbonyls is decreased to less than 90’ in order to increase the overlap of the CO a* orbitals with the filled d,, orbital while overlap with the vacant dyz orbital decreases. Intensity measurements for the carbonyl infrared stretches of this series of Tp’(C0)2W(N(R)R’) complexes indicate that the acute angle between the carbonyls is maintained in solution (80°, 1b; 86’, Id; 85’, 4b);by X-ray diffraction the angles between the carbonyls of 4a and 4c are observed to be 74.6(3) and 71.8(3)’, respectively, in the solid state. Synthesis and Reactivity of [Tp’(C0)2W(NR)][PFc]. Tp’(C0)2W(NHR) complexes exhibit ambiphilic behavior at nitrogen and can act as either proton or hydride donors to form nitrene complexes. As discussed earlier, anionic nitrene complexes are formed when Tp’(C0)2W(NHR) [R = Ph (lb), R = CH2Ph (ld), and R = H (le)] compounds are treated with strong bases. Remarkably, the amido hydrogen can also be removed as a hydride. Treatment of Tp’(C0)2W(NHR) [R = But (la),R = Ph (29) (a) Templeton, J. L.; Ward, B. C. J. Am. Chem. SOC.1980, 102, 6568. (b) Kubacek, P.; Hoffmann, R. J.Am. Chem. SOC.1981,103,4320. (c) Templeton, J. L.; Winston, P. B.; Ward, B. C. J.Am. Chem. SOC.1981, 103,7713.

l + + Tp‘(CO)*W=NCPh3 -I+ (8) 6b

Complexes 5a-d and 6a,b are obtained as crystalline solids upon crystallization from CH2C12:Et20 and are stable when stored under nitrogen. The stability of these cationic dicarbonyl nitrene complexes is noteworthy because they contain both a-acceptor and a-donor ligands. The origin of this stability lies in the d2 configuration.2b The single filled d a orbital (d,2-y2) can back-bond to both carbonyl ligands while the two empty d a orbitals (d,, and dy,) are free to interact with the two filled nitrogen p orbitals of the NR2-moiety (Figure 7) thereby fulfilling the electronic demands of both types of ligands. The high infrared carbonyl stretching frequencies for 5a-d and 6a,b (Table 1)are characteristic of an electron deficient metal center. Large two bond tungsten to carbon coupling in the nitrene ligand (26-31 Hz; Table 2) suggests sp hybridization at nitrogen.30 The linear NR unit can be labeled as a nitrene and considered as a four electron donor in the neutral counting formalism, or it can be counted as a six electron donor imido dianion. Ultimately, the choice of which formalism to apply here is a matter of preference. X-ray diffraction studies of [Tp’(C0)2W(NPh)l[PFGI(5b) confirm that the WNC linkage is indeed nearly linear (171.6(6)’) (see Figure 8 for an ORTEP diagram, Table 3 for crystallographic data collection parameters, Table 8 for atomic parameters, and Table 9 for selected bond distances and angles). The W-N bond distance is short (1.755(7)A),consistent with multiple bonding. The angle between the two carbonyl ligands is 93.7(4)’, which allows for optimal a-bonding of the CO a* orbitals with the single, filled d a metal orbital ( d , ~ ~ 2 ) . ~

(30) Feng, S. G.; Luan,L.; White, P. S.; Brookhart, M.; Templeton, J. L.; Young, C. Inorg. Chem. 1991,30, 2582.

1856 Organometallics, Vol. 13, No. 5, 1994

Powell et al.

c7

Q

W

n

Figure 8. ORTEP diagram of [Tp’(C0)2W(NPh)l[PFGI(5b). Cationic complexes which have a methylene unit adjacent to nitrogen, [Tp’(C0)2W(NCH2R)I[PFc] (R = Prn (5c) and R = Ph (5d)),are readily deprotonated at the @-carbonwith Et3N to form azavinylidenecomplexes,Tp’(C0)2W(N=CHR) [R = Prn (7a) and R = Ph (7b), respectively] (eq 9).31The acidity of the hydrogen on the TP’(CO)~WC N C H 2 2 5c, 5d

+

Et3N

I

C TP‘(CO)~W== N=CHR H+

(9)

7a, 7b

R = Pr” (c). Ph (d)

carbon cy to nitrogen is attributed to the electron-accepting role played by the nitrene nitrogen.32 Formation of a neutral product is evident by monitoring the carbonyl stretching frequencies. These frequencies (1923,1815cm-l (7a) and 1942,1830 cm-l(7b)) are somewhat higher than those observed for the Tp’(C0)2W(N(R)R’) complexes (la-e and 4a-c) (see Table 1)which is consistent with net oxidative removal of dihydrogen which formally relates the NHCH2R and N=CHR ligands. The VN+ frequencies (1628 cm-l (7a) and 1559 cm-l (7b)) are typical for azavinylidene complexes.33 Large two-bond tungsten to carbon coupling (27 Hz (7a) and 26 Hz (7b)), as in the cationic nitrene complexes, is indicative of a linear WNC linkage.30 Protonation of the azavinylidenecomplexes (7a and 7b) with HBF4 re-forms the corresponding cationic nitrene complexes Tp’(C0)2W(NCH2R)+(eq 9). These azavinylidene complexes (7a,b) appear to have a plane of symmetry at room temperature, as judged by lH and 13CNMR spectroscopy. The pyrazole ring protons of the Tp’ ligand show two sets of resonances in a 2:l ratio, and the two carbonyl ligands exhibit a single 13Cresonance (the 18 protons of the six methyl groups of the Tp’ ligand appear in a 6:3:3:6 ratio). Low temperature lH NMR experiments with 7a suggest that this apparent mirror plane is caused by rapid rotation around the WNC axis. As 7a is cooled, the signal at 2.20 ppm, which integrates for six protons (two equivalent CH3 groups of Tp’), (31) Recent publications on azavinylidene complexes: (a) Daniel, T.; Miiller, M.; Werner, H. Inorg. Chem. 1991,30,3118 and ref 2 therein. (b) Feng, S. G.; Templeton, J. L.J. Am. Chem. SOC.1989,111,6477. ( c ) Feng, S. G.; White, P. S.; Templeton, J. L. Organometallics 1993,12,1765. (d) Feng, S. G.; White, P. S.; Templeton, J. L. Organometallics 1993, 12, 2131. (32) (a) Chatt, J.;Dosser,J.; Leigh, G. J. J.Chem. SOC.,Chem. Commun. 1972,1243. (b) Hughes, D. L.; Ibrahim, S. K.; Macdonald, C. J.; Ali, H. M.; Pickett, C. J. J. Chem. SOC.,Chem. Commun. 1992, 1762. (33) (a) Farmery, K.; Kilner, M.; Midcalf, C. J. Chem. SOC.A 1970, 2279. (b) Bercaw, J. E.; Davies, D. L.; Wolczanski, P. T. Organometallics 1986,5,443. ( c ) Erker, G.; Fromberg, W.; Atwood, J. L.; Hunter, W. E. Angew. Chem., Int. Ed. Engl. 1984,23, 68.

I

2 4

I

I

l

I

(

I

l

I

I

I

I

I

I

I

2.2

Figure 9. Variable temperature lH NMR spectra of the Tp’ methyl signals of Tp’(CO)2W(N=CHPrn) (7a) in CD2C12 ( i denotes impurities).

b

Px

Px

Figure 10. Drawings of the metal dr-nitrogen PP and nitrogen pr-carbon PP interactions for Tp’(CO)BW(N=CHR) (7a,b). broadens until the coalescence temperature (-80 “C) is reached (Figure 9). Upon further cooling, two distinct resonances, each integrating for three protons, at 2.21 and 2.14 ppm, are observed ((6:3:3:3:3) pattern for the six Tp’ methyls). AG* for this process is 9.6 kcal/mol. At low temperatures the rate of rotation of the WNC unit is no longer rapid on the NMR time scale, and the HCR plane aligns itself perpendicular to the plane that bisects the Tp’ ligand and the two carbonyl ligands (Figure 10). Consequently, the molecule has overall C1 symmetry. Here, as in the amido complexes [Tp’(C0)2W(N(R)R’) (la-e and 4a-c)], maximal T orbital interaction occurs when the pyorbital of nitrogen interacts with the tungsten dyzorbital (Figure 10). Because the WN and NC P systems are necessarily orthogonal, the HCR fragment is expected to lie orthogonal to the Tp’(C0)2W mirror plane, i.e. in the yz plane. In a similar low temperature lH NMR experiment with 7b, significant broadening is observed for one of the Tp’ methyl signals although the coalescence temperature is not reached even at -105 “C. Low barriers

Organometallics, Vol. 13, No. 5, 1994 1857

Tungsten Imido Complexes

Scheme 1

5b

8

8’

kobs = 7.2 S-l AG*= 16.5 kcaVmol -70 O C

l b syn

to rotation have been reported for other azavinylidene c0mplexes.3~ An indication of the electrophilic nature of the nitrene nitrogen in [Tp’(C0)2W(NR)I[PFsl is the formation of Tp’(CO)zW(NHR) [R = But (la) and R = Ph (lb)] on addition of LiBH4 to [Tp’(C0)2W(NR)I[PF6] (5a and 5b, respectively) (eq 10). Mechanistic studies carried out at

LiBH,

[Tp’( C0)ZW CNR][PFB] 5a, 5 b

CH3CN

Tp’( C0)ZW

N(H)R

(10)

la,lb R=Bu‘(E),Ph(b)

low temperature (-70 “C) with [Tp’(CO)zW(NPh)I[PF61 (5b) indicate that hydride initially attacks at a carbonyl carbon to form a formyl complex, Tp’(CO)(C(O)H)W(NPh) (81, which then undergoes hydride migration to nitrogen (Scheme 1). The formyl intermediate (8) is characterized by C1 symmetry which is reflected in the 1 : l : l pattern for the three pyrazole protons of the Tp’ ligand in the lH NMR spectrum at -70 “C. The formyl hydrogen appears at 16.5 ppm (in CD3CN) and is strongly = 20 H z ) . ~The ~ terminal coupled to tungsten (VWH carbonyl and formyl carbons are located at 259 and 293 ppm (~JHc = 132 Hz), re~pectively.~~ The terminal carbonyl is evident in the infrared spectrum as a strong absorption at 1948 cm-l, while a weak absorption at 1680 cm-l is assigned to the formyl carbonyl.35When this formyl complex is warmed from -70 “C, fluxional behavior is observed, as two of the three pyrazole proton signals broaden in the ‘H NMR spectrum. At -41 OC these signals coalesce and lead to a rate constant for site exchange of 40 s-l, corresponding to AG* = 11.7 kcal/mol. This fluxional behavior is attributed to degenerate hydride migration from the formyl to the carbonyl ligand, 8 + 8’. (34) (a) Erker, G.; Fromberg, W.; Kriiger, C.; Raabe, E. J. Am. Chem. SOC.1988,110, 2400. (b) Dormond, A.; Aaliti, A.; Elbouadili, A.; Moise, C. J. Organomet. Chem. 1987, 329, 187. (35) (a) Casey, C. P.; Andrews, M. A.; Rinz, J. E. J. Am. Chem. SOC. 1979,101,741. (b) Tam, W.; Wong, W.-K.; Gladysz, J. A. J.Am. Chem. SOC.1979,101,1589. (c) Casey, C. P.; Andrews, M. A.; McAlister, D. R.; Rinz, J. E. J.Am. Chem. SOC.1980, 102, 1927. (d) Gladysz, J. A. Adv. Organomet. Chem. 1982, 20, 1 and references therein.

l b anti

At low temperature (-70 “C) the rate of hydride migration from carbon to nitrogen is determined to be first order (kobs = 7.2 X lo4 s-l, AG* = 16.5 kcal/mol), and the 1 : l ratio of the syn and anti isomers of Tp’(C0)zW(NHPh) (lb) represents the kinetically controlled ratio since the interconversion of these isomers at this temperature is exceedingly slow (from the rate data for interconversion (see above) the t l p can be estimated as greater than lo7 days). This hydride migration from carbon to nitrogen has been determined to be intramolecular by crossover experiments which are described in detail in a previous communication.26b Although this reaction occurs by initial attack of the hydride reagent at the carbonyl ligand, the net reaction is, nevertheless, addition of hydride at nitrogen and provides one example of an electrophilic nitrene ligand. Synthesis and Reactivity of Tp’(C0)2WN (9). Deprotonation of the parent nitrene complex, [Tp’(CO)zW(NH)l[PFsl (6a), with Et3N or KH leads to the formation of a new dicarbonyl species with carbonyl stretching frequencies at 2041 and 1944 cm-l. By lH NMR spectroscopy the characteristic 2:l pattern for the protons of the three pyrazole rings of the Tp’ ligand indicates the presence of a mirror plane. Although this complex has not been isolated, spectroscopic data are consistent with formation of the neutral nitrido complex, Tp’(C0)zWN (9) (eq l l ) . 3 6 The d2 configuration in this complex and, 7+

Tp’(C0)zW =NH

Et3N or KN

* Tp’(C0)ZW E N :

6a

9

consequently, the metal d a interactions with the nitrogen p a orbitals are analogous to those of the linear cationic nitrene complexes (vide supra; Figure 7, R = lone pair). The product of the reaction of Tp’(C0)zWI with [(Ph3P)zNI[NJ at low temperature appears spectroscopically to be identical to 9 (eq 12). This synthesis provides a direct route to 9 and supplied ample material for reactivity studies. ~~

~

~~~~~

~

~

~

_

_

_

_

(36) For structurallycharacterized nitridocomplexes,see: (a)Reference 24c. (b) Groves, J. T.;Takahashi, T.; Butler, W. M. Inorg. Chem. 1983, 22,884. (c)Hill, C. L.; Hollander, F. J.J. Am. Chem. SOC.1982,104,7318.

Po we11 et a 1.

1858 Organometallics, Vol. 13, No. 5, 1994

-

-78 ..

Tp’(CO),WI 2

oc.

+ [(Ph3P),Nl[N31 CHzCls

Tp’(CO),W=N: 9

(12)

The nitrido species (9) reacts with a variety of electrop h i l e ~ to 3 ~yield either dicarbonyl or monocarbonyl imido products. Protonation of 9 with HBF4 regenerates the parent nitrene (6a). Similarly, reaction of 9 with [PhsCI[PFsl yields the cationic dicarbonyl triphenylmethyl nitrene (6b). Methylation of 9 is effected with MeOTf (Tf = -S02CF3) to give [Tp’(C0)2W(NMe)l[OTfl (10). Equation 13 summarizes the reactions of 9 with electrophiles to form cationic dicarbonyl nitrene complexes. Tp’(CO),W S N :

RX

[TP’(CO)~Ws N R ] [ X ] R

9

H Ph3C Me

I 1 X

complex

BF4

6a

T:‘6(

(13)

QC17

6b 10

Figure 11. ORTEP diagram of Tp’(CO)ClW(NTs) (lla).

Attempts to generate Tp’(C0)2WNR+ complexes with more strongly electron-withdrawing R groups attached to nitrogen yield instead monocarbonyl products. When 9 is treated with electrophiles such as tosyl chloride, acetyl chloride, or acetic anhydride, only neutral monocarbonyl products, Tp’(CO)(X)W(NR) (R = Ts, X = C1, lla; R = C(O)CH3, X = C1, llb; R = C(O)CH3, X = OC(O)CH3, 1 IC) (eq 14),are observed. ‘H and 13CNMR data indicate Tp’(C0)zW G N :

9

RX

Tp’(CO)(X) W

-co R

Ts -C(O)CH3 -C(O)CHs

t NR

I E; 1

( 14)

X

complex

-OC(O)CHs

lla lib 11 c

that the three pyrazole rings of the Tp’ ligand are magnetically inequivalent in these complexes. The acetyl carbons (NC(O)CH3) of l l b and l l c are strongly coupled to tungsten (2Jw-c = 35 Hz), indicating a nearly linear imido linkage.30 Elemental analyses of l l a and l l b confirm the presence of a chlorine atom in these molecules. X-ray diffraction of a single crystal of l l a confirms the presence of the chlorine atom in the tungsten coordination sphere and reveals the structure of the tosyl imido ligand. Figure 11 shows an ORTEP diagram of lla. The crystallographic data were obtained under the conditions listed in Table 3. The atomic parameters are presented in Table 10. The structure exhibits disorder of the C1and CO ligands attached to tungsten. This disorder was modeled as 60% C1/40% CO [C1(1),O(1)l and 40% C1/ 60 76 CO [C1(2),O(2)l. Selected bond distances and angles are presented in Table 11. Salient data include the W-N bond distance of 1.78(1)A,which is indicative of tungstennitrogen multiple bonding and the 173(1)O W(l)-N(2)S(1) bond angle which confirms sp hybridization at nitrogen. Although we do not have data relevant to the mechanism of these reactions, we postulate that the cationic dicarbonyl complexes, [Tp’(CO)zW(NR)I [XI, are formed initially. When R is a strong electron-withdrawing (37) For examples of addition of electrophiles to terminal nitride units, see: (a) Bevan, P. C.; Chatt, J.; Dilworth, J. R.; Henderson, R. A.; Leigh, G. J. J . Chem. SOC.,Dalton Trans. 1982, 821. (b) Reference 32b.

group such as tosyl or acetyl and X- is a more highly coordinating counterion such as chloride or acetate, the metal center is sufficiently electron deficient to render the cationic dicarbonyl complex unstable with respect to displacement of CO by the counterion X-.

Summary Amido complexes, Tp’(CO)zW(NHR), have been synthesized and utilized as precursors to both anionic, Tp’(C0)2W(NR)-, and cationic, Tp’(C0)2W(NR)+,dicarbony1 tungsten nitrene complexes. The anionic imido complexes,Tp’(CO)zW(NR)-, react with alkylating agents to give dialkylamido complexes, Tp’(CO)zW(NRR’). Tp’(C0)2W(NCH2R)+ complexes can be deprotonated with Et3N to give neutral azavinylidene complexes, Tp’(C0)2W(N=CHR). Low temperature NMRstudies of the reaction of LiBH4 with Tp’(C0)2W(NPh)+ indicated that the hydride reagent initially attacks a t a carbonyl carbon to form a formyl complex, Tp’(CO)(CHO)W(NPh), which then undergoes intramolecular hydride migration from the formyl carbon to nitrogen to form the amido complex, Tp’(C0)2W(NHPh). The nitrido complex, Tp’(C0)2WN, was synthesized by deprotonation of the parent cationic nitrene complex, Tp’(C0)2W(NH)+,and also by reaction of Tp’(C0)2WI with [(PhsP)] [N31. This nitrido species reacts with electrophiles (RX) to give both cationic, [Tp’(C0)2W(NR)l[XI, and neutral, Tp’(CO)XW(NR),nitrene complexes.

Experimental Section Materialsand Methods. All manipulationswere carried out under a dry nitrogen atmosphere with standard Schlenk techniques. Solvents were dried and distilled under nitrogen by standard meth0ds.~8Literature methods were used to prepare Tp’(C0)~W1,3~ Tp’(C0)2WI,@and [(PhsP)zN][Ns].41 All other reagents were used as obtained from commercial sources. (38) Gordon,A. J.;Ford, R. A. The Chemist’s Companion;Wiley: New York, 1972. (39) Feng, S. G.;Philipp,C.C.; Gamble,A.S.; White,P. S.;Templeton, J. L. Organometallics 1991, 10, 3504. (40) (a) Reference 26c. (b)Philipp, C. C.;Young, C. G.; White, P. S.; Templeton, J. L. Inorg. Chem. 1993,32, 5437. (41) Martinsen, A.; Songstad, J. Acta Chem. Scand. 1977, A31, 645.

Organometallics, Vol. 13, No. 5, 1994

Tungsten Imido Complexes Table 2. Selected’

la, Tp’(C0)2W(NHBut) lb,Tp’(C0)2W(NHPh)

IC, TP’(CO)~W(NHBU”)

NMR Data4c for ComJexes la-e,

1859

4a-c, 5a-d, 6a,b, 7a,b, 10, and lla-c

14.15 (l), br s, NH 1.39 (9), S, C(CH3)3, 15.33,br s, NH, major isomer 13.0,br s, NH, minor isomer isomer ratio 7.51 (1) d 13.7,br t, NH, major isomer; ’JH-H= 8 HZ 11.9,br t, NH, minor isomer isomer ratio 6:1 (1) 3.40(2),dt, CH2Prn;3 J ~ = - 8~ Hz, 3 J ~ =- 8~HZ

255.6 (2) ‘Jw+ = 176 HZ 255.6 (2) 161.3 (l), ipso,Ph ‘Jw-c = 173 HZ d 254.6 (2)

73.5 (l), CH2Prn

IJw-c = 177 HZ e

e

Id,Tp’(C0)2W(NHCH2Ph)

le, Tp’(C0)2W(NH2) 4a, Tp’(CO)2W(N(Ph)CH2Ph) 4b, Tp’(CO)2W(N(Me)CH2Ph)

13.57,t, NH, major isomer; 3 J ~ =- 8~ Hz 11.82,br t, NH, minor isomer isomer ratio 6:l (1) 4.47 (2),d, NCH2Ph; 3 J w - ~ = 50 Hz, 3 J ~ =- 8~ HZ d 13.50(l), br s 11.60(1), b r s 4.42(2),S, NCH2Ph d 2.07 (3),NMe 4.75 (2),NCH2Ph d 3.30(3), Me 2.16 (3), Me 1.59 (91,s, C(CH3)S 7.50(5), m, NPh 3.77 (2),t, NCH2Prn;’JH-H = 8 HZ

e 4.81 (2),NCH2Ph; 3 J w - ~ = 8 HZ d 9.8 (l), br, NH

d 3.02(I), t, NCHPr”; 3 J ~ =- 6~Hz 3 J w - ~ = 6 Hz e

7b, Tp’(C0)2W(N-CHPh) 10, [Tp’(C0)2WWMe)l [PFd lla, Tp’(CO)ClW(NTs)

llb,Tp’(CO)ClW(NC(O)CH3)

3.79 (l), NCHPh; 3 J ~=-4 ~ Hz d 3.67 (3), Me; 3JW-H = 10 HZ Ts (AA’XX’ spin system) 6A, 7.77 (2);6X, 7.36 (2); J s p p ~=- ~ 8 HZ g (3), P-Me (Ts) 1.73 (3), NC(O)CH3

llc,Tp’(CO)(OC(O)CH3)W(NC(O)CH3) g (3), NC(O)CH3 g (31,oc(o)cff3

254.7 (2)

78.4 (1) NCH2Ph d

254.7 (2) IJw-c = 175 HZ 254.1 (2) IJw+ = 178 HZ 254.7 (2) 1Jw-c = 175 HZ

78.7 (l), NCH2Ph d 57.2 (l), NCH3 87.6 (l), NCH2Ph d 70.6 (l), Me 254.8 (2) lJw+ 177 HZ 61.4(l), Me 216.6 (2) 74.0(l), C(CH3)s; 2Jw-c = 23 HZ IJw+ = 157 HZ 30.6 (3),C(CH3)3 216.9 (2) 153.6,ipso, Ph; 2 J= 3 1~Hz ~ 1Jw-c = 153 hz d 216.8 (2) 67.5 (l), NCH2Prn;2 J= 26~Hz ~ ‘Jw+ = 158 HZ e 216.0 (2) 71.9 (l), NCH2Ph; 2Jw 2.5a(I))

RF RW GoF

4eCHzC12 BC~ICIH~~N~O~W 804.23 triclinic Pi 11.452(2) 11.597(2) 14.144(2) 86.78( 1) 84.41(1) 64.37( 1) 1685.4(4) 2 1.585 798.55 0.25 X 0.25 X 0.30 20 Mo K& (0.710 73) 5 < 28 < 45 3.70 8/28 (-1 1 ,O,-15) to (1 2,12,15) 5015 4399 3910 0.037 0.046 1.66

4c BC I 9Hz8N702W 581.13 triclinic Pi 1 1 . 1 5 1 (4) 11.702(3) 10.391(4) 93.46(3) 108.56(3) 63.20(3) 1141.7(7) 2 1.690 569.97 0.25 X 0.25 X 0.15 20 M o K a (0.710 73) 5